Series 6, Vertical Floor-Mount Units

MISSION CRITICAL Air Conditioning Systems Series 6, Vertical Floor-Mount Units Installation Manual ClimateWorx International Inc. 14 Chelsea Lane, Brampton, Ontario, Canada L6T 3Y4

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Table of Contents Table of Contents... 3 Site Preparation... 4 Location Consideration... 5 Positioning of Indoor units... 5 Positioning of Outdoor Heat Rejection Devices... 5 Dimensional Details... 6 Electrical Installation... 7 Power Feeding... 7 Interconnecting Wiring... 7 Refrigerant Pipework Installation... 8 Recommended Pipe Size for Remote Condenser... 9 Evacuation... 9 Fan Speed Control System... 10 Charging... 10 Head Pressure Control System... 12 Charging... 12 Chilled-water / Water / Glycol Pipework Installation... 14 Piping Connection Size:... 14 Appendix A: Dimensional Drawings... 15 Appendix B: Piping Schematic Diagrams... 21 Appendix C: Electrical Schematic Diagrams... 29 3

Site Preparation In order to maximize operating efficiency and performance, the following areas should be observed at the site-planning stage: - The room should be surrounded with a vapor seal to eliminate moisture migration through the building structure. Windows should be sealed and at least double-glazed to prevent sweating. All door jams should fit tightly and should not have any grilles in them. Polyethylene film type ceiling, vinyl wallpaper or plastic based paint on the walls and slabs are recommended to minimize absorption and transmission of moisture into the room. - Owing to a generally small population, a typical room should have fresh air kept at only about 5% of the re-circulated air. This provides enough ventilation for personnel and pressurizes the room to prevent dust from entering through leaks. The incoming fresh air must be filtered very closely, and preferably pretreated. Otherwise heating, cooling, humidifying and dehumidifying loads of the incoming fresh air should be taken into account in determining total loading requirements. - All cables and piping should be carefully routed to lower resistance to the distribution of conditioned air and to avoid the blockage of air-paths to any portion of the room. As a good practice, all cables and piping running under the raised floor should be mounted horizontally and whenever possible, routed to run in parallel with the air-path. - In order to obtain the most effective air distribution, units should not be located too close together. Attention should be taken to avoid locating the units in an alcove or an extreme end of a long narrow room. 4

Location Consideration Positioning of Indoor units The Series 6 units are designed to be free standing on an accessible raised flooring system provided with sufficient pedestal supports underneath. A minimum raised floor height of 12 (300mm) is required. However, it is highly recommended to use a separate floor stand as a support, which is independent of the raised floor system. This allows the unit to be installed prior to erecting the raised flooring system thus providing much easier access to piping and electrical connections. The floor stand or unit should be isolated using a suitable isolation method. ClimateWorx OEM floor stands use a two-nut system for the floor stand feet. Use both nuts, the top nut for leveling and the bottom nut to lock the leveling nut in place. The room layout should provide 27-1/2 (700mm) service clearance in the front of the unit for the routine service and maintenance. Right-side access increases serviceability. Note: Packaged air cooled units must be positioned with back of unit facing the outside wall with opening in the outside wall to match the opening in the unit. This opening should be covered on the outside with a grille to meet local safety and building codes but must not restrict discharge or intake air flow. Positioning of Outdoor Heat Rejection Devices The outdoor heat rejection devices such as air-cooled condensers and glycol coolers should be located as close to the indoor unit as possible. From a security and environment standpoint, the outdoor heat rejection devices should be installed away from public access and occupied spaces where low ambient sound level is required. In order to avoid short circuiting and inter unit re-circulation, outdoor heat rejection devices should be located at least 1.2m (4 ft.) away from any walls or obstructions or 2.4m (8ft), from adjacent units. To ensure maintenance-free operation, outdoor heat rejection devices should be located away from the areas that are continuously exposed to loose dirt and foreign materials that may clog the coil. The outdoor heat rejection devices should be firmly secured on steel supports or concrete plinths. 5

Dimensional Details The following tables summarize the dimensional detail drawing number for Series 6 units with standard options. Please refer to Appendix A for the dimensional detail drawings. For units with a special option or configuration, please consult factory for details. - Upflow/ Downflow Systems Model -02-03 -04-05 6AU S6DD101 S6DD101 S6DD101 S6DD101 6AD S6DD102 S6DD102 S6DD102 S6DD102 6CU S6DD101 S6DD101 S6DD101 S6DD101 6CD S6DD102 S6DD102 S6DD102 S6DD102 6WU S6DD101 S6DD101 S6DD101 S6DD101 6WD S6DD102 S6DD102 S6DD102 S6DD102 6GU S6DD101 S6DD101 S6DD101 S6DD101 6GD S6DD102 S6DD102 S6DD102 S6DD102 - Air Cooled Packaged Systems Model -02-03 -04-05 6AD/U S6DAXP500 S6DAXP500 S6DAXP500 S6DAXP500 - Ducted Return Air Systems Model -02-03 -04-05 6AU S6DD103 S6DD103 S6DD103 S6DD103 6AD S6DD104 S6DD104 S6DD104 S6DD104 6CU S6DD103 S6DD103 S6DD103 S6DD103 6CD S6DD104 S6DD104 S6DD104 S6DD104 6WU S6DD103 S6DD103 S6DD103 S6DD103 6WD S6DD104 S6DD104 S6DD104 S6DD104 6GU S6DD103 S6DD103 S6DD103 S6DD103 6GD S6DD104 S6DD104 S6DD104 S6DD104 6

Electrical Installation Power Feeding All models are fitted with a 3-pole main isolator, neutral and earth terminal, which are located at the lower right corner of the power panel. The isolator and terminals will accept cables up to AWG #2 (35mm²) gauge. The power cables should be sized in accordance with local and national codes. Refer to the "Electrical Data" section in the Technical Data Manual for current requirements. Interconnecting Wiring Internal wiring for all Series 6 is completed and tested prior to delivery. Numbered terminal blocks for field installed control wiring are provided next to the main power isolator at the lower right corner of the power panel. The numbered terminal blocks will accept control wiring up to #12 AWG (4mm²) gauge. The terminal assignments are listed as follows: Terminal Function Requirement 11-12 Standby enable Normally open output 13-14 Common alarm (General) Normally open output 21-22 Common alarm (Critical) Normally open output 15-16 Remote on / off Normally open dry contact input 17-18 Standby start Normally open dry contact input 19-20 Fire alarm Normally closed dry contact input 23 thru 28 Condenser/Pump interlock Normally open dry contact output 31-32 Compressor disable (optional) Normally open dry contact input 35-36 Remote on/off Interrupt (optional) Normally open dry contact input 37-38 Unit Status (optional) Normally open dry contact output 39-42 Custom Fault1/2 (optional) Normally closed dry contact input 43-44 Liquid High Limit (optional) Normally closed dry contact input 49-50 Hum/ Reheat disable (optional) Normally open dry contact input 57-58 Damper Motor Interlock (optional)normally open dry contact output 59-60 Damper End Switch (optional) Normally open dry contact input 7

Refrigerant Pipework Installation Good practice should always be followed when connecting refrigerant piping in direct expansion systems. As many of the operational problems encountered in a refrigeration system can be traced back to improper design and installation of refrigerant piping, it is essential that the following guidelines be observed: - Use clean and dehydrated refrigeration quality tubing with both ends sealed. - Cut and form tubes carefully to avoid getting dirt or metal particles into the refrigeration lines. Never use a hacksaw to cut the tubing. - Once the system is open, complete the work as quickly as possible to minimize ingress of moisture and dirt into the system. Always put caps on ends of tubes and parts not being worked on. - To prevent scaling and oxidation inside the tubing, pass an inert gas such as nitrogen through the line while carrying out brazing, silver soldering or any other welding processes. - It is recommended that quality refrigeration solder (95% tin, 5% silver) be used for its excellent capillary action. - Use minimum amount of solder flux to prevent internal contamination of the piping. Use flux with care as it is usually acidic in nature. - Install a trap at the bottom of the vertical riser of a hot gas line and a trap for every 20 ft. (6m) in elevation to collect refrigerant and lubrication oil during off cycle. A discharge line trap is an important function both during the compressor on and during the compressor off cycle. During the on cycle, the trap collects oil droplets and carries them efficiently up the elevated discharge line. During the off cycle, the traps captures and retains oil residing on the pipe walls that would otherwise drain back to the compressor head, causing damage on startup. - Install inverted trap whenever a condenser is located above the compressor. An inverted trap or check valve should be installed at the condenser inlet and outlet to prevent liquid refrigerant from flowing backwards into the compressor during off cycles. - Insulate the suction line and insulate liquid lines that may be subjected to high heat gains. Insulate low level discharge lines to avoid burning due to accidental contact. - Design and arrange refrigerant piping for the remote condenser in such a way so that adequate velocity of refrigerant can be maintained to prevent oil trapping. Under sizing discharge lines will reduce compressor capacity and increase compressor load. Over sizing discharge lines increases the initial cost of the project and can reduce the refrigerant gas velocity to a level where oil is not returned to the compressor.recommended pipe sizes are tabulated as follows: 8

Recommended Pipe Size for Remote Condenser Evacuation Hot Gas Line Model - 6AD / 6AU -02-03 -04-05 50 ft. equivalent pipe length in. 7 / 8 7 / 8 7 / 8 7 / 8 100 ft. equivalent pipe length in. 7 / 8 7 / 8 7 / 8 7 / 8 150 ft. equivalent pipe length in. 7 / 8 7 / 8 7 / 8 7 / 8 200 ft. equivalent pipe length in. 7 / 8 7 / 8 7 / 8 7 / 8 Liquid Line Model - 6AD / 6AU -02-03 -04-05 50 ft. equivalent pipe length in. 1 / 2 1 / 2 1 / 2 1 / 2 100 ft. equivalent pipe length in. 1 / 2 1 / 2 1 / 2 1 / 2 150 ft. equivalent pipe length in. 1 / 2 1 / 2 1 / 2 1 / 2 200 ft. equivalent pipe length in. 1 / 2 1 / 2 1 / 2 1 / 2 The procedure for leakage testing and evacuation of the system is as follows: 1. Disconnect all line voltage fuses except the fuses for control transformers. Using the test mode, energize fan and all solenoid valves. (See M52 User s Guide) Open liquid line hand valve. 2. Connect a gauge manifold to the compressor suction and discharge rotalock valve. 3. Close the compressor discharge and suction ports and open all service valves. 4. Charge the system with dry nitrogen to approximately 150 psig (not to exceed 350 psig). 5. Leave pressure in system for at least 12 hours. If pressure holds, continue with next step. If the pressure drops detect and seal leak before continuing. 6. Release all pressure. Connect a vacuum pump to the compressor suction and discharge rotalock valves with refrigerant or high vacuum hoses. Provide an isolating valve and a pressure gauge for pressure checking. 7. Evacuate the system to an absolute pressure not exceeding 1500 microns. Break the vacuum to 2psig with dry nitrogen. Repeat the evacuation process and then re-break the vacuum with dry nitrogen. 8. Open the compressor discharge and suction ports. Evacuate to an absolute pressure not exceeding 500 microns. Let the vacuum pump run without interruption for minimum two hours. 9

Fan Speed Control System The fan speed control system maintains not only a constant condensing pressure over a wide range of climatic conditions but also high sensible cooling for the evaporator so that re-humidification is rarely required throughout the year. A pressure-sensitive fan speed controller is employed in the fan speed control system. It regulates the condenser head pressure at low ambient temperatures by varying the airflow volume through the condenser. Upon engaging the interlock contact in the indoor unit, the fan speed controller will directly sense the changes in the refrigerant head pressure and vary the output voltage from 15% to 97% of the applied voltage. Charging Calculate the total charge required using this formula: Indoor Unit Charge + Liquid Line Charge + Condenser Charge + Hot gas Line Charge = Total Charge Proper performance of the system depends largely on proper charging. Adhere to the following guidelines for charging: 1. Open the main isolator and insert the fuses for the fans, control transformers and the compressor. 2. Close the main isolator and allow the compressor crankcase heater to operate for at least one hour. 3. Connect the gauge manifold to both discharge and suction rotalock valves, with a common connection to the refrigerant cylinder. Purge the lines by opening the refrigerant cylinder vapor valve. 4. Connect the refrigerant cylinder to recovery unit and charge system with 90% of calculated amount. 5. Start the unit using the test mode to energize the main fan and compressor. Please make sure outdoor condenser (if any) is powered. 6. Add additional refrigerant to the system until the sight glass is clear of bubbles and subcooling is measured between 10-15psi. 7. Run system to maintain a hot gas (discharge) pressure based on refrigerant used (R407C @240psi and R22 a @225psi) then re-check subcooling, Add refrigerant if subcooling has dropped below 10psi. 10

8. The system is now correctly charged for operating under fan speed control. It is a good practice to weigh the amount of additional refrigerant that was added and keep a record of the total charge in the system. Note: Packaged Air cooled systems come completely factory charged (except when a factory split is ordered). Fan speed control is provided by a discharge pressure transducer which signals a Variable Frequency Drive (VFD) to maintain a constant head pressure. This is factory set to perform at peak performance and does not need to be set or adjusted on site. 11

Head Pressure Control System For condensers possibly subjected to extremely low ambient temperature, it is recommended that a head pressure control system be installed. This avoids starving the evaporator coil, with the consequence of oil clogging; short cycling on low pressure control, reduction of the system capacity and erratic expansion valve operation. A drop in the condensing pressure often occurs in air-cooled systems as a result of low ambient conditions encountered during fall-winter-spring operation. Head pressure control renders part of the condenser surface inactive. The reduction of active condensing surface results in a rise in condensing pressure and hence provides a sufficient liquid line pressure for normal system operation. The head pressure control system allows operation at extremely low ambient temperature down to -40 F. ClimateWorx uses a two-valve head pressure control with receiver, for factory ordered condensers. The ORI is located in the liquid drain line between the condenser and the receiver, and the ORD is located in a hot gas line bypassing the condenser. During periods of low ambient temperature, the condensing pressure falls until it approaches the setting of the ORI valve. The ORI then throttles, restricting the flow of liquid from the condenser. This causes refrigerant to back up in the condenser thus reducing the active condenser surface. This raises the condensing pressure. Since it is really the receiver pressure that needs to be maintained, the bypass line with the ORD is required. The ORD opens after the ORI has offered enough restriction to cause the differential between condensing pressure and receiver pressure to exceed 20psi. The hot gas flowing through the ORD serves to heat up the cold liquid being passed by the ORI. Thus the liquid reaches the receiver warm and with sufficient pressure to assure proper expansion valve operation. As long as sufficient refrigerant charge is in the system, the two valves modulate the flow automatically to maintain proper receiver pressure regardless of outside ambient. Charging Calculate the total charge required using this formula: Indoor Unit Charge + Liquid Line Charge + Condenser Charge + Hot gas Line Charge + 20% of Receiver volume = Total Charge When head pressure control is utilized, there must be enough refrigerant to flood the condenser at the lowest expected ambient and still have enough charge in the system for proper operation. After completing the evacuation procedures as in the fan speed control system, follow the following guidelines for charging: 12

1. Open the main isolator and insert the fuses for the fans, control transformers and the compressor. 2. Close the main power and allow the compressor crankcase heater to operate for at least one hour. 3. Connect the gauge manifold to both discharge and suction rotalock valves, with a common connection to the refrigerant cylinder. Purge the lines by opening the refrigerant cylinder vapor valve. 4. Connect the refrigerant cylinder to recovery unit and charge system with 90% of calculated amount. 5. Start the unit using the test mode to energize the main fan and compressor. Please make sure outdoor condenser (if any) is powered. 6. Add additional refrigerant to the system until the sight glass is clear of bubbles. 7. Run system to maintain a hot gas (discharge) pressure based on refrigerant used (R407C @240psi and R22 a @225psi) by adjusting ORI valve(s) then re-check subcooling, Add refrigerant if subcooling has dropped below 10psi. 8. The system is now correctly charged for operating under head pressure control at the ambient temperature charging is being carried out. It is a good practice to weigh the amount of additional refrigerant that was added and keep a record of the total charge in the system. 9. If the system is designed to operate at ambient below the ambient that exists during charging, additional charge will have to be added now. Method to Determine Additional Refrigerant Charge to Operate to an Expected Minimum Ambient Temperature Example for KS11-078-1 Ambient Temp at Time of Charging = 60 F to Operate to -30 F Step 1. At the ambient temperature at the time of charging the system (e.g 60 F) Read from the table % of Condenser to be Flooded (e.g - 10 %) Step 2. At the expected minimum ambient Temperature (e.g - - 30 F ) Read from the table - % of the Condenser to be Flooded (e.g - 77 %) Step 3. Calculate the difference of the above two values ( 77 % - 10 % = 67 % ) Step 4. From the Air Cooled Condenser Guide read Winter Flooded ( -40 F ) Refrigerant Charge ( 6.4 lbs ) Step 5. Multiply the value found in Step 4 by the difference in % s calculated in Step 3. Additional Required Charge = 6.4 lb * ( 67 % ) = 4.30 lb / Condenser ( If Two (2) Circuit Condenser 2.15 lb / Ref Circuit 13

Chilled-water / Water / Glycol Pipework Installation The Chilled-water / Water / Glycol pipework should be installed in accordance with the following recommendations: - A manual shut-off valve should be installed at the supply and return pipes of each indoor unit for routine service and emergency isolation of the unit. - Joints installed inside the room must be kept to a minimum. The system drain discharge point should be installed outside the room. - Piping inside the building should be insulated to eliminate the possibility of condensation under low ambient conditions. - Always use the reverse return system when two or more indoor units are served by the same source. - For condensing water supplied from a cooling tower, adequate filtration and an inhibitor should be added in correct quantities to prevent the formation of scale and corrosion. - Only ethylene glycol containing a corrosion inhibitor should be used. Automotive anti-freeze is unacceptable and must not be used in the Glycol system. - Concentration of glycol required depends on the minimum ambient temperature. The following glycol concentration is recommended: Piping Connection Size: % of ethylene glycol by weight Minimum operating temperature C ( F) 10 0 (32) 20-5 (23) 30-11.6 (11) 40-20 (-4) 50-32.2 (-26) Model no. suffix 02 03 04 05 Liquid line -odm 1/2 1/2 1/2 1/2 Hot gas line -odm 5/8 5/8 5/8 7/8 Humidifier drain -odm 3/4 3/4 3/4 3/4 Humidifier water in -odm 1/4 1/4 1/4 1/4 Cooling coil condensate -odm 3/4 3/4 3/4 3/4 Chilled water (when req d) -odm 1-1/8 1-1/8 1-1/8 1-1/8 Condenser water (when req d) -odm 1-1/8 1-1/8 1-1/8 1-1/8 Glycol solution (when req d) -odm 1-5/8 1-5/8 1-5/8 1-5/8 Odm Outside diameter of copper pipe in inches for soldering 14

Appendix A: Dimensional Drawings Drawing Title SERIES 6 - Upflow Dimensional Detail SERIES 6 - Downflow Dimensional Detail SERIES 6 Upflow System with Ducted Return Plenum Dimensional Detail SERIES 6 - Downflow System with Ducted Return Plenum Dimensional Detail SERIES 6 - Upflow or Downflow System with Packaged Air cooled condenser Drawing No. S6DD101 S6DD102 S6DD103 S6DD104 S6DXAP500 15

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Appendix B: Piping Schematic Diagrams Drawing Title SERIES 6 Chilled Water System Schematic SERIES 6 Air Cooled System Schematic SERIES 6 Air Cooled System Schematic with Hot Gas Bypass SERIES 6 Water Cooled System Schematic SERIES 6 Water Cooled System Schematic with Hot Gas Bypass SERIES 6 Glycol Cooled System Schematic SERIES 6 Glycol Cooled System Schematic with Hot Gas Bypass SERIES 6 Air Cooled Packaged System Schematic Drawing No. S6DS401 S6DS101 S6DS102 S6DS201 S6DS202 S6DS301 S6DS302 S6DS103 21

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Appendix C: Electrical Schematic Diagrams Drawing Title Electric Schematic Packaged Air-Cooled General, Electric Schematic Air-Cooled General, Electric Schematic Water/ Glycol-Cooled General, Electric Schematic Chilled Water General, Electric Schematic Dual Cooling Air General, Electric Schematic Dual Cooling Water or Glycol General, Electric Schematic Free Cooling General, Electric Schematic Field Wiring Standby Start/ Standby Enable, For automatic change over Electric Schematic Co-Work I2C Interconnection Link Electric Schematic RS485 ModBus RTU Connection, Serial Communication Link Electric Schematic Embedded Connection, Serial to Serial or Ethernet Communication Link remote power Electric Schematic Embedded Connection, Serial to Serial or Ethernet Communication Link factory power Drawing No. ES9005 ES9030 ES9065 ES9050 ES9030 ES9040 ES9070 M52ES05 M52ES1003 M52ES1004 M52ES1005 M52ES1006 29

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